/*
 * Copyright 2007 ZXing authors
 *
 * Licensed under the Apache License, Version 2.0 (the "License");
 * you may not use this file except in compliance with the License.
 * You may obtain a copy of the License at
 *
 *      http://www.apache.org/licenses/LICENSE-2.0
 *
 * Unless required by applicable law or agreed to in writing, software
 * distributed under the License is distributed on an "AS IS" BASIS,
 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 * See the License for the specific language governing permissions and
 * limitations under the License.
 */

package com.ailiwean.core.zxing.core.qrcode.detector;

import com.ailiwean.core.zxing.core.DecodeHintType;
import com.ailiwean.core.zxing.core.FormatException;
import com.ailiwean.core.zxing.core.NotFoundException;
import com.ailiwean.core.zxing.core.ResultPoint;
import com.ailiwean.core.zxing.core.ResultPointCallback;
import com.ailiwean.core.zxing.core.common.BitMatrix;
import com.ailiwean.core.zxing.core.common.DetectorResult;
import com.ailiwean.core.zxing.core.common.GridSampler;
import com.ailiwean.core.zxing.core.common.PerspectiveTransform;
import com.ailiwean.core.zxing.core.common.detector.MathUtils;
import com.ailiwean.core.zxing.core.qrcode.decoder.Version;

import java.util.Map;

/**
 * <p>Encapsulates logic that can detect a QR Code in an image, even if the QR Code
 * is rotated or skewed, or partially obscured.</p>
 *
 * @author Sean Owen
 */
public class Detector2 {

    private final BitMatrix image;
    private ResultPointCallback resultPointCallback;

    public Detector2(BitMatrix image) {
        this.image = image;
    }

    protected final BitMatrix getImage() {
        return image;
    }

    protected final ResultPointCallback getResultPointCallback() {
        return resultPointCallback;
    }

    /**
     * <p>Detects a QR Code in an image.</p>
     *
     * @return {@link DetectorResult} encapsulating results of detecting a QR Code
     * @throws NotFoundException if QR Code cannot be found
     * @throws FormatException   if a QR Code cannot be decoded
     */
    public DetectorResult detect() throws NotFoundException, FormatException {
        return detect(null);
    }

    /**
     * <p>Detects a QR Code in an image.</p>
     *
     * @param hints optional hints to detector
     * @return {@link DetectorResult} encapsulating results of detecting a QR Code
     * @throws NotFoundException if QR Code cannot be found
     * @throws FormatException   if a QR Code cannot be decoded
     */
    public final DetectorResult detect(Map<DecodeHintType, ?> hints) throws NotFoundException, FormatException {

        resultPointCallback = hints == null ? null :
                (ResultPointCallback) hints.get(DecodeHintType.NEED_RESULT_POINT_CALLBACK);

        FinderPatternFinder2 finder = new FinderPatternFinder2(image, resultPointCallback);
        FinderPatternInfo info = finder.find(hints);

        return processFinderPatternInfo(info);
    }

    protected final DetectorResult processFinderPatternInfo(FinderPatternInfo info)
            throws NotFoundException, FormatException {

        FinderPattern topLeft = info.getTopLeft();
        FinderPattern topRight = info.getTopRight();
        FinderPattern bottomLeft = info.getBottomLeft();

        float scaleRatio = (float) (Math.random() * 0.6f + 0.3f);
        float moduleSize = calculateModuleSize(topLeft, topRight, bottomLeft) * scaleRatio;
        if (moduleSize < 1.0f) {
            throw NotFoundException.getNotFoundInstance();
        }
        int dimension = computeDimension(topLeft, topRight, bottomLeft, moduleSize);
        Version provisionalVersion = Version.getProvisionalVersionForDimension(dimension);
        int modulesBetweenFPCenters = provisionalVersion.getDimensionForVersion() - 7;

        AlignmentPattern alignmentPattern = null;
        // Anything above version 1 has an alignment pattern
        if (provisionalVersion.getAlignmentPatternCenters().length > 0) {

            // Guess where a "bottom right" finder pattern would have been
            float bottomRightX = topRight.getX() - topLeft.getX() + bottomLeft.getX();
            float bottomRightY = topRight.getY() - topLeft.getY() + bottomLeft.getY();

            // Estimate that alignment pattern is closer by 3 modules
            // from "bottom right" to known top left location
            float correctionToTopLeft = 1.0f - 3.0f / modulesBetweenFPCenters;
            int estAlignmentX = (int) (topLeft.getX() + correctionToTopLeft * (bottomRightX - topLeft.getX()));
            int estAlignmentY = (int) (topLeft.getY() + correctionToTopLeft * (bottomRightY - topLeft.getY()));
            // Kind of arbitrary -- expand search radius before giving up
            for (int i = 4; i <= 16; i <<= 1) {
                try {
                    alignmentPattern = findAlignmentInRegion(moduleSize,
                            estAlignmentX,
                            estAlignmentY,
                            i);
                    break;
                } catch (NotFoundException re) {
                    // try next round
                }
            }
            // If we didn't find alignment pattern... well try anyway without it
        }

        PerspectiveTransform transform =
                createTransform(topLeft, topRight, bottomLeft, alignmentPattern, dimension);

        BitMatrix bits = sampleGrid(image, transform, dimension);
        ResultPoint[] points;
        if (alignmentPattern == null) {
            points = new ResultPoint[]{bottomLeft, topLeft, topRight};
        } else {
            points = new ResultPoint[]{bottomLeft, topLeft, topRight, alignmentPattern};
        }
        return new DetectorResult(bits, points);
    }

    private static PerspectiveTransform createTransform(ResultPoint topLeft,
                                                        ResultPoint topRight,
                                                        ResultPoint bottomLeft,
                                                        ResultPoint alignmentPattern,
                                                        int dimension) {
        float dimMinusThree = dimension - 3.5f;
        float bottomRightX;
        float bottomRightY;
        float sourceBottomRightX;
        float sourceBottomRightY;
        if (alignmentPattern != null) {
            bottomRightX = alignmentPattern.getX();
            bottomRightY = alignmentPattern.getY();
            sourceBottomRightX = dimMinusThree - 3.0f;
            sourceBottomRightY = sourceBottomRightX;
        } else {
            // Don't have an alignment pattern, just make up the bottom-right point
            bottomRightX = (topRight.getX() - topLeft.getX()) + bottomLeft.getX();
            bottomRightY = (topRight.getY() - topLeft.getY()) + bottomLeft.getY();
            sourceBottomRightX = dimMinusThree;
            sourceBottomRightY = dimMinusThree;
        }

        return PerspectiveTransform.quadrilateralToQuadrilateral(
                3.5f,
                3.5f,
                dimMinusThree,
                3.5f,
                sourceBottomRightX,
                sourceBottomRightY,
                3.5f,
                dimMinusThree,
                topLeft.getX(),
                topLeft.getY(),
                topRight.getX(),
                topRight.getY(),
                bottomRightX,
                bottomRightY,
                bottomLeft.getX(),
                bottomLeft.getY());
    }

    private static BitMatrix sampleGrid(BitMatrix image,
                                        PerspectiveTransform transform,
                                        int dimension) throws NotFoundException {

        GridSampler sampler = GridSampler.getInstance();
        return sampler.sampleGrid(image, dimension, dimension, transform);
    }

    /**
     * <p>Computes the dimension (number of modules on a size) of the QR Code based on the position
     * of the finder patterns and estimated module size.</p>
     */
    private static int computeDimension(ResultPoint topLeft,
                                        ResultPoint topRight,
                                        ResultPoint bottomLeft,
                                        float moduleSize) throws NotFoundException {
        int tltrCentersDimension = MathUtils.round(ResultPoint.distance(topLeft, topRight) / moduleSize);
        int tlblCentersDimension = MathUtils.round(ResultPoint.distance(topLeft, bottomLeft) / moduleSize);
        int dimension = ((tltrCentersDimension + tlblCentersDimension) / 2) + 7;
        switch (dimension & 0x03) { // mod 4
            case 0:
                dimension++;
                break;
            // 1? do nothing
            case 2:
                dimension--;
                break;
            case 3:
                throw NotFoundException.getNotFoundInstance();
        }
        return dimension;
    }

    /**
     * <p>Computes an average estimated module size based on estimated derived from the positions
     * of the three finder patterns.</p>
     *
     * @param topLeft    detected top-left finder pattern center
     * @param topRight   detected top-right finder pattern center
     * @param bottomLeft detected bottom-left finder pattern center
     * @return estimated module size
     */
    protected final float calculateModuleSize(ResultPoint topLeft,
                                              ResultPoint topRight,
                                              ResultPoint bottomLeft) {
        // Take the average
        return (calculateModuleSizeOneWay(topLeft, topRight) +
                calculateModuleSizeOneWay(topLeft, bottomLeft)) / 2.0f;
    }

    /**
     * <p>Estimates module size based on two finder patterns -- it uses
     * {@link #sizeOfBlackWhiteBlackRunBothWays(int, int, int, int)} to figure the
     * width of each, measuring along the axis between their centers.</p>
     */
    private float calculateModuleSizeOneWay(ResultPoint pattern, ResultPoint otherPattern) {
        float moduleSizeEst1 = sizeOfBlackWhiteBlackRunBothWays((int) pattern.getX(),
                (int) pattern.getY(),
                (int) otherPattern.getX(),
                (int) otherPattern.getY());
        float moduleSizeEst2 = sizeOfBlackWhiteBlackRunBothWays((int) otherPattern.getX(),
                (int) otherPattern.getY(),
                (int) pattern.getX(),
                (int) pattern.getY());
        if (Float.isNaN(moduleSizeEst1)) {
            return moduleSizeEst2 / 7.0f;
        }
        if (Float.isNaN(moduleSizeEst2)) {
            return moduleSizeEst1 / 7.0f;
        }
        // Average them, and divide by 7 since we've counted the width of 3 black modules,
        // and 1 white and 1 black module on either side. Ergo, divide sum by 14.
        return (moduleSizeEst1 + moduleSizeEst2) / 14.0f;
    }

    /**
     * See {@link #sizeOfBlackWhiteBlackRun(int, int, int, int)}; computes the total width of
     * a finder pattern by looking for a black-white-black run from the center in the direction
     * of another point (another finder pattern center), and in the opposite direction too.
     */
    private float sizeOfBlackWhiteBlackRunBothWays(int fromX, int fromY, int toX, int toY) {

        float result = sizeOfBlackWhiteBlackRun(fromX, fromY, toX, toY);

        // Now count other way -- don't run off image though of course
        float scale = 1.0f;
        int otherToX = fromX - (toX - fromX);
        if (otherToX < 0) {
            scale = fromX / (float) (fromX - otherToX);
            otherToX = 0;
        } else if (otherToX >= image.getWidth()) {
            scale = (image.getWidth() - 1 - fromX) / (float) (otherToX - fromX);
            otherToX = image.getWidth() - 1;
        }
        int otherToY = (int) (fromY - (toY - fromY) * scale);

        scale = 1.0f;
        if (otherToY < 0) {
            scale = fromY / (float) (fromY - otherToY);
            otherToY = 0;
        } else if (otherToY >= image.getHeight()) {
            scale = (image.getHeight() - 1 - fromY) / (float) (otherToY - fromY);
            otherToY = image.getHeight() - 1;
        }
        otherToX = (int) (fromX + (otherToX - fromX) * scale);

        result += sizeOfBlackWhiteBlackRun(fromX, fromY, otherToX, otherToY);

        // Middle pixel is double-counted this way; subtract 1
        return result - 1.0f;
    }

    /**
     * <p>This method traces a line from a point in the image, in the direction towards another point.
     * It begins in a black region, and keeps going until it finds white, then black, then white again.
     * It reports the distance from the start to this point.</p>
     *
     * <p>This is used when figuring out how wide a finder pattern is, when the finder pattern
     * may be skewed or rotated.</p>
     */
    private float sizeOfBlackWhiteBlackRun(int fromX, int fromY, int toX, int toY) {
        // Mild variant of Bresenham's algorithm;
        // see http://en.wikipedia.org/wiki/Bresenham's_line_algorithm
        boolean steep = Math.abs(toY - fromY) > Math.abs(toX - fromX);
        if (steep) {
            int temp = fromX;
            fromX = fromY;
            fromY = temp;
            temp = toX;
            toX = toY;
            toY = temp;
        }

        int dx = Math.abs(toX - fromX);
        int dy = Math.abs(toY - fromY);
        int error = -dx / 2;
        int xstep = fromX < toX ? 1 : -1;
        int ystep = fromY < toY ? 1 : -1;

        // In black pixels, looking for white, first or second time.
        int state = 0;
        // Loop up until x == toX, but not beyond
        int xLimit = toX + xstep;
        for (int x = fromX, y = fromY; x != xLimit; x += xstep) {
            int realX = steep ? y : x;
            int realY = steep ? x : y;

            // Does current pixel mean we have moved white to black or vice versa?
            // Scanning black in state 0,2 and white in state 1, so if we find the wrong
            // color, advance to next state or end if we are in state 2 already
            if ((state == 1) == image.get(realX, realY)) {
                if (state == 2) {
                    return MathUtils.distance(x, y, fromX, fromY);
                }
                state++;
            }

            error += dy;
            if (error > 0) {
                if (y == toY) {
                    break;
                }
                y += ystep;
                error -= dx;
            }
        }
        // Found black-white-black; give the benefit of the doubt that the next pixel outside the image
        // is "white" so this last point at (toX+xStep,toY) is the right ending. This is really a
        // small approximation; (toX+xStep,toY+yStep) might be really correct. Ignore this.
        if (state == 2) {
            return MathUtils.distance(toX + xstep, toY, fromX, fromY);
        }
        // else we didn't find even black-white-black; no estimate is really possible
        return Float.NaN;
    }

    /**
     * <p>Attempts to locate an alignment pattern in a limited region of the image, which is
     * guessed to contain it. This method uses {@link AlignmentPattern}.</p>
     *
     * @param overallEstModuleSize estimated module size so far
     * @param estAlignmentX        x coordinate of center of area probably containing alignment pattern
     * @param estAlignmentY        y coordinate of above
     * @param allowanceFactor      number of pixels in all directions to search from the center
     * @return {@link AlignmentPattern} if found, or null otherwise
     * @throws NotFoundException if an unexpected error occurs during detection
     */
    protected final AlignmentPattern findAlignmentInRegion(float overallEstModuleSize,
                                                           int estAlignmentX,
                                                           int estAlignmentY,
                                                           float allowanceFactor)
            throws NotFoundException {
        // Look for an alignment pattern (3 modules in size) around where it
        // should be
        int allowance = (int) (allowanceFactor * overallEstModuleSize);
        int alignmentAreaLeftX = Math.max(0, estAlignmentX - allowance);
        int alignmentAreaRightX = Math.min(image.getWidth() - 1, estAlignmentX + allowance);
        if (alignmentAreaRightX - alignmentAreaLeftX < overallEstModuleSize * 3) {
            throw NotFoundException.getNotFoundInstance();
        }

        int alignmentAreaTopY = Math.max(0, estAlignmentY - allowance);
        int alignmentAreaBottomY = Math.min(image.getHeight() - 1, estAlignmentY + allowance);
        if (alignmentAreaBottomY - alignmentAreaTopY < overallEstModuleSize * 3) {
            throw NotFoundException.getNotFoundInstance();
        }

        AlignmentPatternFinder alignmentFinder =
                new AlignmentPatternFinder(
                        image,
                        alignmentAreaLeftX,
                        alignmentAreaTopY,
                        alignmentAreaRightX - alignmentAreaLeftX,
                        alignmentAreaBottomY - alignmentAreaTopY,
                        overallEstModuleSize,
                        resultPointCallback);
        return alignmentFinder.find();
    }

}
